Dynamics of rocking podium structures

102

Summary This paper characterizes the ability of natural ground motions to induce rocking demands on rigid structures. In particular, focusing on rocking blocks of different size and slenderness subjected to a large number of historic earthquake records, the study unveils the predominant importance of the strong‐motion duration to rocking amplification (ie, peak rocking response without overturning). It proposes original dimensionless intensity measures (IMs), which capture the total duration (or total impulse accordingly) of the time intervals during which the ground motion is capable of triggering rocking motion. The results show that the proposed duration‐based IMs outperform all other examined (intensity, frequency, duration, and/or energy‐based) scalar IMs in terms of both “efficiency” and “sufficiency.” Further, the pertinent probabilistic seismic demand models offer a prediction of the peak rocking demand, which is adequately “universal” and of satisfactory accuracy. Lastly, the analysis shows that an IM that “efficiently” captures rocking amplification is not necessarily an “efficient” IM for predicting rocking overturning, which is dominated by the velocity characteristics (eg, peak velocity) of the ground motion.

Section: Introductionmentioning

confidence: 99%

Rocking amplification and strong‐motion duration

Giouvanidis

Dimitrakopoulos

2018

102

“…Such structure consists of rocking columns with curved base extensions placed on the ground floor and capped by a rigid beam that supports a superstructure, the rocking podium structures described by Bachmann et al 55 An assumption that the superstructure behaves as rigid, as used in design of actual buildings in the USSR, 67 has been shown 34,55 to simplify the seismic response analysis of such structures (because the superstructure mass can be lumped in the cap-beam) while maintaining sufficient accuracy. Such structure consists of rocking columns with curved base extensions placed on the ground floor and capped by a rigid beam that supports a superstructure, the rocking podium structures described by Bachmann et al 55 An assumption that the superstructure behaves as rigid, as used in design of actual buildings in the USSR, 67 has been shown 34,55 to simplify the seismic response analysis of such structures (because the superstructure mass can be lumped in the cap-beam) while maintaining sufficient accuracy.…”

Section: Rolling and Rocking Frame Structuresmentioning

confidence: 99%

“…Since then, a plethora of papers on rocking structures has been published studying these structures theoretically [2][3][4][5][6][7][8][9][10][11][12][13][14][15][16] and experimentally. This application is usually termed "kinematic isolation" [50][51][52][53][54][55] : The bottom floor comprises rocking concrete rocking columns and is essentially an intentionally designed soft story with large displacement capacity. [44][45][46][47][48][49] What has received less attention in the literature published in English is that rocking has been used in the USSR since 1960s (and is still used in former USSR states) as a seismic response modification technique for buildings.…”

Section: Introductionmentioning

confidence: 99%

“…[17][18][19][20][21][22] The rocking oscillator has been used in bridge engineering, [23][24][25][26][27][28][29][30][31][32][33][34] as well as to model the behavior of masonry walls, [35][36][37][38][39][40] of ancient temples, [41][42][43] of unanchored equipment, and of museum artifacts. 55 The uplift of the soft story columns acts like a mechanical fuse and limits the seismic forces transmitted to the superstructure. This application is usually termed "kinematic isolation" [50][51][52][53][54][55] : The bottom floor comprises rocking concrete rocking columns and is essentially an intentionally designed soft story with large displacement capacity.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Rolling and rocking of rigid uplifting structures

Bachmann

Vassiliou

Stojadinović

2019

Self Cite

Summary Allowing structures to uplift modifies their seismic response; uplifting works as a mechanical fuse and limits the forces transmitted to the superstructure. However, engineers are generally reluctant to construct an unanchored structure because the system could overturn due to lacking redundancy. Using a safety factor for the design of a flat rocking foundation, ie, designing it wider, goes against the main idea of this seismic modification method as the force demand for the structure increases. We propose to extend the flat base of a rocking block with curved extensions to better protect the block from overturning, yet not prevent its uplifting. After investigating the seismic response of such rocking blocks, we extend the study to investigate the seismic response of rolling and rocking frames comprising columns with curved base extensions. The equations of motion are derived, time history analyses are performed, and rocking spectra are constructed. We draw two important conclusions: (a) the response of a class of rocking oscillators with curved base extensions is equivalent to the response of a flat‐base rocking oscillators of the same slenderness, yet larger size; (b) the rotation demand on two negative stiffness rocking and rolling oscillators with the same uplifting acceleration and the same size is roughly the same as long as the rocking oscillators are not close to overturning. The above findings can serve as a basis for the rational seismic design of structures supported on rocking columns with curved bases, a system that has been used since the 1960s.

“…The uplift of rocking columns works as a mechanical fuse and limits the design forces of both the foundation and the superstructure. The idea has been applied in the former Soviet Union to isolate buildings . In the rest of the world, it has been proposed as an isolation method for bridges, where limiting the design forces could be crucial to avoid pile foundations.…”

Section: Introductionmentioning

confidence: 99%

Seismic response of a wobbling 3D frame

Vassiliou

2017

Self Cite

Summary This paper investigates the 3D response of a slab supported by wobbling columns. The columns are not allowed neither to slide nor to roll out of their initial position. An analytical model is proposed, the equations of motion are derived, and they are solved numerically. The paper concludes that the addition of the slab makes the columns more stable. In fact, the system is almost equivalent to the response of a solitary column with the same aspect ratio yet larger size. However, it is also shown that the system is less stable than its planar counterpart and that planar analysis can only qualitatively describe the behavior of 3D structures. A case study shows that the concept could be used as a seismic isolation technique for bridges. However, more research need to be performed on defining proper intensity measures for uplifting structures, as it is shown that there is large record‐to‐record variability, even when intensity measures developed for rocking structures are used.